Method and apparatus for decoding/encoding a video signal

ABSTRACT

A method of decoding a video signal is disclosed. The method includes decoding a bit stream of a base layer, obtaining flag information, obtaining information indicating an obtaining position of parameters. The parameters includes at least one of information on a phase shift of a chrominance signal and offset information. The method further includes obtaining the information on the phase shift of the chrominance signal based on the flag information and the information indicating the obtaining position of the parameters, and obtaining the offset information based on the flag information and the information indicating the obtaining position of the parameters. The method further includes up-sampling the picture of the base layer, and decoding a bit stream of an enhanced layer based on the reference picture up-sampled from the picture of the base layer, the information on the phase shift of the chrominance signal and the offset information.

This application is a National Phase entry of PCT Application number PCT/KR2007/005812 filed on Nov. 19, 2007, which claims priority under 35 U.S.C. §§119(e), 120 and 365(c) to U.S. Provisional Application Nos. 60/859,532, and 60/897,051 filed on Nov. 17, 2006 and Jan. 24, 2007, respectively.

TECHNICAL FIELD

The present invention relates to a scheme for coding a video signal.

BACKGROUND ART

Generally, compression coding means a series of signal processing for transmitting digitalized information via a communication circuit or storing the digitalized information in a format suitable for a storage medium. There exist audio, video, characters and the like as targets for compression coding. Particularly, a scheme for performing compression coding on video is called video sequence compression. And, a video sequence is generally characterized in having spatial redundancy and temporal redundancy.

Specifically, a scalable-video-coded bit stream can be decoded partially and selectively. For instance, a decoder having low complexity is capable of decoding a base layer and a bit stream of a low data rate is extractable for transport via network having a limited capacity. In order to generate an image of high resolution more gradually, it is necessary to enhance a quality of image step by step.

DISCLOSURE OF THE INVENTION Technical Problem

Specifically, a scalable-video-coded bit stream can be decoded partially and selectively. For instance, a decoder having low complexity is capable of decoding a base layer and a bit stream of a low data rate is extractable for transport via network having a limited capacity. In order to generate an image of high resolution gradually, it is necessary to enhance a quality of image step by step.

Technical Solution

Accordingly, the present invention is directed to a scheme for coding a video signal that substantially obviates one or more of the problems due to limitations and disadvantages of the related art.

An object of the present invention is to provide a method of enhancing a coding efficiency in coding a video signal.

Another object of the present invention is to provide a method of minimizing a transmission of information associated with inter-layer prediction in case that an area in a enhanced layer is not corresponding to a reference layer.

Another object of the present invention is to provide a method of minimizing a transmission of information associated with inter-layer prediction in a manner of confirming configuration information on a scalable-video-coded bit stream.

Another object of the present invention is to provide a method of minimizing a transmission of information associated with inter-layer prediction in a manner of confirming information indicating whether inter-layer prediction is executed.

An object of the present invention is to provide a method of minimizing transmission of information associated with inter-layer prediction by confirming quality identification information.

Another object of the present invention is to provide a method of enhancing coding efficiency of a video signal by defining information indicating a handling of a slice boundary.

A further object of the present invention is to provide a method of raising a coding efficiency in a manner of confirming configuration information of a scalable-video-coded bit stream in a proper position.

ADVANTAGEOUS EFFECTS

Accordingly, the present invention provides the following effects or advantages.

First of all, it is checked whether a current block in a enhanced layer can be predicted by using inter-layer prediction. In case that the current block in the enhanced layer is not predicted by using the inter-layer prediction, it is unnecessary to transmit coding information used for the inter-layer prediction. Hence, the present invention raises a coding efficiency. Secondly, by identifying configuration information of a scalable-video-coded bit stream in a proper position, whereby transmission information associated with inter-layer prediction can be minimized. For instance, by identifying information indicating whether inter-layer prediction is executed and/or quality identification information, transmission information associated with inter-layer prediction can be minimized. And, the present invention enables parallel processing by defining information indicating a handling of a slice boundary. Therefore, coding efficiency of a video signal can be considerably enhanced using the above-explained various methods.

DESCRIPTION OF DRAWINGS

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention.

In the drawings:

FIG. 1 is a schematic block diagram of a scalable video coding system according to the present invention;

FIG. 2 and FIG. 3 are structural diagrams for configuration information on a scalable sequence addible to a scalable-video-coded bit stream and pictures for describing the configuration information according to one embodiment of the present invention, respectively;

FIG. 4 is a diagram for a cropping relation between a sampled base layer and an enhanced layer;

FIG. 5 and FIG. 6 are diagrams for syntaxes relevant to macroblock and sub-macroblock predictions through inter-layer prediction according to one embodiment of the present invention, respectively;

FIG. 7 is a diagram of a syntax relevant to residual prediction through inter-layer prediction according to one embodiment of the present invention;

FIG. 8 is a diagram of a syntax structure to perform deblocking filtering in accordance with a presence or non-presence of inter-layer prediction execution according to an embodiment of the present invention;

FIG. 9 is a diagram of a syntax structure to obtain offset information indicating a position difference between an up-sampled picture and a current: picture in accordance with a presence or non-presence of inter-layer prediction execution according to an embodiment of the present invention;

FIG. 10 is a diagram of a syntax structure to obtain flag information indicating whether to restrict a use of intra-block in a reference layer in accordance with a presence or non-presence of inter-layer prediction execution according to an embodiment of the present invention; and

FIG. 11 is a structural diagram of a syntax for obtaining adaptive prediction information in accordance with a presence or non-presence of inter-layer prediction execution according to one embodiment of the present invention.

BEST MODE

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims thereof as well as the appended drawings.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described, a method of decoding a video signal according to the present invention includes decoding a bit stream of a first layer, obtaining a flag information indicating whether inter-layer prediction is carried out on a current block of a second layer, obtaining at least one offset information indicating a position difference between an up-sampled picture of the first layer used for the inter-layer prediction and a current picture of the second layer based on the flag information, and up-sampling a reference picture of the first layer using at least the one offset information.

Preferably, the method further includes obtaining an information indicating whether a parameter for the up-sampling exists in a corresponding area of the second layer. And, at least the one offset information is obtained based on the information indicating whether the parameter for the up-sampling exists in the corresponding area of the second layer.

More preferably, the method further includes obtaining an information on a phase shift of a chrominance signal based on the information indicating whether the parameter for the up-sampling exists in the corresponding area of the second layer, wherein the first layer is up-sampled using the information on the phase shift of the chrominance signal.

In this case, the information on the phase shift of the chrominance signal is obtained based on an information indicating a chroma format. Moreover, the information on the phase shift of the chrominance signal includes a phase shift information on a horizontal direction and a phase shift information on a vertical direction.

More preferably, the method further includes obtaining a quality identification information for identifying a quality of the current block of the second layer, wherein the offset information is obtained based on the quality identification information.

Preferably, the second layer differs from the first layer in a screen ratio or a spatial resolution, the first layer being from a same video signal of the second layer.

To further achieve these and other advantages and in accordance with the purpose of the present invention, an apparatus for decoding a video signal includes a base layer decoding unit decoding a bit stream of a first layer, a first header information obtaining unit obtaining a flag information indicating whether inter-layer prediction is carried out on a current block of a second layer, a second header information obtaining unit obtaining at least one offset information indicating a position difference between an up-sampled picture of the first layer used for the inter-layer prediction and a current picture of the second layer based on the flag information, and an up-sampling unit up-sampling a reference picture of the first layer using at least the one offset information.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

Mode for Invention

Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

First of all, compression coding of video signal data takes spatial redundancy, spatial redundancy, scalable redundancy, and inter-view redundancy into consideration.

Compression coding scheme, which takes scalable redundancy into consideration, is just an embodiment of the present invention. And, the technical idea of the present invention is applicable to temporal redundancy, spatial redundancy, inter-view redundancy, and the like. In the present disclosure, coding can include both concepts of encoding and decoding. And, coding can be flexibly interpreted to correspond to the technical idea and scope of the present invention.

In a bit sequence configuration of a video signal, there exists a separate layer structure called a NAL (network abstraction layer) between a VCL (video coding layer) dealing with a moving picture encoding process itself and a lower system that transports and stores encoded information. An output generated from an encoding process is VCL data and is mapped by NAL unit prior to transport or storage. Each NAL unit includes compressed video data or RBSP (raw byte sequence payload: result data of moving picture compressions that is the data corresponding to header information.

The NAL unit basically includes two parts, a NAL header and an RBSP. The NAL header includes flag information (nal_ref_idc) indicating whether a slice becoming a reference picture of the NAL unit is included and information (nal_unit_type) indicating a type of the NAL unit. Compressed original data is stored in the RBSP. And, RBSP trailing bit is added to a last portion of the RBSP to represent a length of the RBSP as an 8-bit multiplication. As the type of the NAL unit, there is IDR (instantaneous decoding refresh) picture, SPS (sequence parameter set), PPS (picture parameter set), SEI (supplemental enhancement information), or the like.

So, if the information (nal_unit_type) indicating the type of the NAL unit indicates a scalable video coded slice, coding efficiency can be raised by adding various configuration informations relevant to the scalable coding. For instance, it is able to add flag information indicating whether a current access unit is an instantaneous decoding refresh (hereinafter abbreviated IDR) access unit, dependency identification information indicating spatial scalability, quality identification information, flag information (no_inter_layer_pred_flag) indicating whether inter-layer prediction is used, priority identification information, and the like. This will be explained in detail with reference to FIG. 2 later.

In the standardization, requirements for various profiles and levels are set to enable implementation of a target product with an appropriate cost. In this case, a decoder should meet the requirements decided according to the corresponding profile and level. Thus, two concepts, ‘profile’ and ‘level’ are defined to indicate a function or parameter for representing how far the decoder can cope with a range of a compressed sequence. And, a profile identifier (profile_idc) can identify that a bit stream is based on a prescribed profile. The profile identifier means a flag indicating a profile on which a bit stream is based. For instance, in H.264/AVC, if a profile identifier is 66, it means that a bit stream is based on a baseline profile. If a profile identifier is 77, it means that a bit stream is based on a main profile. If a profile identifier is 88, it means that a bit stream is based on an extended profile. Moreover, the profile identifier can be included in a sequence parameter set.

So, in order to handle a scalable sequence, it needs to be identified whether an inputted bit stream is a profile for a scalable sequence. If the inputted bit stream is identified as a profile for a scalable sequence, it is necessary to add a syntax to enable at least one additional information for a scalable sequence to be transmitted. In this case, the profile for the scalable sequence, which is an additional scheme of H.264/AVC, indicates a profile mode for handling scalable video. Since SVC is an additional scheme to conventional AVC, it may be more efficient to add a syntax as additional information for an SVC mode rather than add an unconditional syntax. For instance, when a profile identifier of AVC indicates a profile for a scalable sequence, if information on a scalable sequence is added, it is able to raise coding efficiency.

Various embodiments to provide an efficient video signal decoding method are explained as follows.

FIG. 1 is a schematic block diagram of a scalable video coding system according to the present invention.

In order to provide a sequence optimized for various communication environments and various terminals, a sequence provided to a terminal should be diversified. If a sequence optimized for each terminal is provided to the corresponding terminal, it means that a single sequence source is prepared for a combination value of various parameters including the number of transmission frames per a second, resolution, the number of bits per a pixel, and the like. So, the provision of the optimized sequence imposes a burden on a contents provider. Therefore, a contents provider encodes an original sequence into a compressed sequence data of high bit rate. In case of receiving a sequence request made by a terminal, the contents provider decodes the original sequence, encodes it into a sequence data suitable for a sequence processing capability of the terminal, and then provides the encoded data to the terminal. Since this transcoding is accompanied with the encoding-decoding-encoding process, it is unable to avoid a time delay generated in the course of providing a sequence. So, a complicated hardware device and algorithm are additionally required.

On the other hand, scalable video coding (SVC) is a coding scheme for encoding a video signal with a best image quality to enable a partial sequence of a generated picture sequence to be represented as a sequence by being decoded. In this case, the partial sequence may mean a sequence consisting of frames intermittently selected from a whole sequence. For a picture sequence encoded by SVC, a sequence size can be reduced for a Low bit rate using spatial scalability. And an image quality of sequence can be lowered using quality scalability as well. In this case, a picture sequence having a small-size screen and/or a low frame number per second can be called a base layer and a sequence having a relatively large-size screen and/or a relatively high frame number per second can be called an enhanced or enhancement layer.

A picture sequence encoded by the above-mentioned scalable scheme enables a sequence representation of a low image quality in a manner of receiving and processing the partial sequence only. Yet, if a bit rate gets lowered, an image equality is considerably degraded. To solve a problem of the degraded image quality, it is able to provide a separate auxiliary picture sequence for a low bit rate, e.g., a picture sequence having a small-size screen and/or a low frame number per second. Such an auxiliary sequence can be called a base layer and a main picture sequence can be called an enhanced or enhancement layer.

In describing various embodiments for inter-layer prediction, the present disclosure uses the concept including a first layer and a second layer. For instance, the second layer can have a spatial resolution or screen ratio different from that of the first layer. And, the second layer can have an image quality different from that of the first layer. For detailed instance, the first layer can be a base layer and the second layer can be an enhanced layer. In performing inter-layer prediction, the first layer can be a reference layer and the second layer can be a current layer. The base and enhanced layers explained in the following description are just exemplary, which does not put restriction on the interpretation of the present invention.

The scalable video coding system is explained in detail as follows. First of all, the scalable coding system includes an encoder 102 and a decoder 110. The encoder 102 includes a base layer encoding unit 104, an enhanced layer encoding unit 106, and a multiplexing unit 108. And, the decoder can include a demultiplexing unit 112, a base layer decoding unit 114, and an enhanced layer decoding unit 116. The base layer encoding unit 104 is capable of generating a base bit stream by compressing an inputted sequence signal X(n). The enhanced layer encoding unit 106 is capable of generating an enhanced layer bit stream using the inputted sequence signal X(n) and information generated by the base layer encoding unit 104. And, the multiplexing unit 108 is capable of generating a scalable bit stream using the base layer bit stream and the enhanced layer bit stream.

The generated scalable bit stream is transported to the decoder 110 via a certain channel. The transported scalable bit stream can be discriminated into an enhanced layer bit stream and a base layer bit stream by the demultiplexing unit 112 of the decoder 110. The base layer decoding unit 114 receives the base layer bit stream and then decodes the base layer bit stream into a sequence signal of intra-macroblock and residual and motion information of inter-block. In this case, the corresponding decoding can be carried out based on single loop decoding method.

The enhanced layer decoding unit 116 receives the enhanced layer bit stream, and decodes an output sequence signal Xe(n) with reference to a base layer bit stream reconstructed by the base layer decoding unit 114. In this case, the output sequence signal Xb(n) will be a sequence signal having an image quality or resolution lower than that of the latter output sequence signal Xe(n).

The enhanced layer decoding unit 116 may include a first header information obtaining unit, a second header information obtaining unit, a deblocking filter unit, and an up-sampling unit. The first header information obtaining unit is able to obtain configuration information of a bit stream from a header of NAL. For instance, the first header information obtaining unit is able to obtain quality identification information, information indicating whether inter-layer prediction is used, and the like. The second header information obtaining unit is able to obtain configuration information of a bit stream from a slice header. For instance, the second header information obtaining unit is able to obtain information indicating a handling of a slice boundary in an up-sampling process, information associated with an operation of deblocking filter, information on a phase shift of a chrominance signal, offset information indicating a position difference between pictures, information indicating whether to execute adaptive prediction, and the like. The deblocking filter unit is able to perform deblocking filtering using the information associated with the operation of the deblocking filter. The up-sampling unit is able to up-sample a first layer using the offset information indicating the position difference between pictures for inter-layer prediction. Thus, it is able to perform the inter-layer prediction using the informations on the up-sampled first layer.

Thus, each of the enhanced layer encoding unit 106 and the enhanced layer decoding unit 116 performs coding using inter-layer prediction. The inter-layer prediction may mean that a sequence signal of an enhanced layer is predicted by using motion information and/or texture information of a base layer. In this case, the texture information may mean a image data or a pixel value belonging to a macroblock. For instance, in the inter-layer prediction method, there are an intra base prediction mode or a residual prediction mode. The intra base prediction mode may mean a mode for predicting a block of the enhanced layer based on a corresponding area in the base layer. In this case, the corresponding area in the base layer may mean an area coded in an intra mode. Meanwhile, the residual prediction mode can use a corresponding area, having residual data that is an image difference value, in the base layer. In both case, the corresponding area in the base layer can be enlarged or reduced to use by sampling. The sampling may mean that image resolution is varied. And, the sampling can include resampling, downsampling, upsampling, and the like. For instance, it is able to resample intra samples to perform inter-layer prediction. And, image resolution can be reduced by regenerating pixel data using a downsampling filter. This can be called downsampling. Moreover, several additional pixel data can be made using an upsampling filter to increase image resolution. This can be called upsampling. The resampling can include both concepts of the downsampling and the upsampling. In the present disclosure, the terminology ‘sampling’ can be properly interpreted in accordance with a technical idea and scope of a corresponding embodiment of the present invention.

Meanwhile, a base layer and an enhanced layer are generated for different usages or purposes for the same sequence contents and may differ from each other in spatial resolution, frame rate, bit rate, and the like. In coding a video signal by inter-layer prediction, a non-dyadic case, a ratio of an enhanced layer to a base layer in spatial resolution is not an integer of 2, can be called extended spatial scalability (ESS). For instance, when an enhanced layer is coded by inter-layer prediction for a video signal having a ratio of 16:9 (horizontal:vertical), a case in which a base layer is coded into an image having a ratio of 4:3 may occur. In this case, since the base layer is coded in a cropping state that an original video signal is cropped in part, it is unable to cover a full area of an enhanced layer even if the base layer is enlarged for the inter-layer prediction. So, since the partial area of the enhanced layer fails to have a corresponding area in the upsampled base layer, the partial area may not use the upsampled base layer for inter-layer prediction. Namely, it means that the inter-layer prediction is not applicable to the partial area. In this case, coding informations used for the inter-layer prediction may not be transported. Detailed embodiments for this will be explained in detail with reference to FIGS. 5 to 11.

FIG. 2 and FIG. 3 are structural diagrams for configuration information on a scalable sequence addible to a scalable-video-coded bit stream and pictures for describing the configuration information according to one embodiment of the present invention, respectively;

FIG. 2 shows an example of a configuration of NAL unit enabling configuration informations on a scalable sequence to be added thereto. First of all, the NAL unit can mainly include a NAL unit header and an RBSP (raw byte sequence payload: result data of moving picture compression). The NAL unit header can include identification information (nal_ref_idc) indicating whether the NAL unit includes a slice of a reference picture and information (nal_unit_type) indicating a type of the NAL unit. And, an extension area of the NAL unit header can be limitedly included. For instance, if the information indicating the type of the NAL unit is associated with scalable video coding or indicates a prefix NAL unit, the NAL unit is able to include an extension area of the NAL unit header. In particular, if the nal_unit_type=20 or 14, the NAL unit is able to include the extension area of the NAL unit header. And, configuration informations for a scalable sequence can be added to the extension area of the NAL unit header according to flag information (svc_mvc_flag) capable of identifying whether it is SVC bit stream.

For another instance, if the information indicating the type of the NAL unit is information indicating a subset sequence parameter set, the RBSP can include information on the subset sequence parameter set. In particular, if nal_unit_type=15, the RBSP can include information on a subset sequence parameter set, information on a slice layer, and the like. In this case, the subset sequence parameter set can include an extension area of the sequence parameter set according to profile information. For example, if profile information (profile_idc) is a profile relevant to scalable video coding, the subset sequence parameter set can include an extension area of the sequence parameter set. Alternatively, a sequence parameter set can include an extension area of a sequence parameter set according to profile information. The extension area of the sequence parameter set can include information for controlling characteristics of a deblocking filter for inter-layer prediction, parameters associated with information for an upsampling process, and the like. Various configuration informations on a scalable sequence, e.g., configuration informations that can be included in an extension area of NAL unit header, an extension area of a sequence parameter set, and a slice layer, are explained in detail as follows.

First of all, it is possible to obtain flag information(inter_layer_deblocking filter_control present f lag) indicating whether there exists the information for controlling the characteristics of the deblocking filter for inter-layer prediction from the extension area of the sequence parameter set. And, it is possible to obtain information (extended_spatial_scalability) indicating a position of the parameter associated information for the upsampling process from the extension area of the sequence parameter set. In particular, for example, if extended_spatial scalability=0, it can mean that any parameter for the upsampling process does not exist in a sequence parameter set or a slice header. If extended_spatial scalability=1, it can mean that a parameter for the upsampling process exists in a sequence parameter set. If extended_spatial (scalability=2, it can mean that a parameter for the upsampling process exists in a slice header. Parameters for the up-sampling process will be explained in detail with reference to FIG. 9 later.

Information {circle around (4)} indicating whether inter-layer prediction is used may mean flag information indicating whether inter-layer prediction is used in decoding a coded slice. The flag information can be obtained from an extension area of a NAL header. For instance, if the flag information is set to 1, it may mean that the inter-layer prediction is not used. If the flag information is set to 0, the inter-layer prediction can be used or not in accordance with a coding scheme in a macroblock. This is because the inter-layer prediction in a macroblock unit may be used or not.

Quality identification information {circle around (3)} means information identifying a quality for a NAL unit. In describing the configuration information, FIG. 3 is referred to. For instance, a single picture can be coded into layers differing from each other in quality. In FIG. 3, layers in Spa_Layer0 and Spa_Layer1 can be coded into layers differing from each other in quality. In particular, assuming that information identifying a quality for the NAL unit is named quality_id, layers B1, B2, . . . , B10 can be set to quality_id=0. And, layers Q1, Q2, . . . , Q10 can be set to quality_id=1. Namely, the layers 131, B2, . . . , B10 may mean the layers having the lowest image quality. These are called base pictures. The layers Q1, Q2, . . . , Q10 correspond to layers including the layers B1, B2, . . . , B10 and have image qualities better than those of the layers B1, B2, B10. And, the quality identification information can be defined in various ways. For instance, the quality identification information can be represented as 16 steps.

Identification information indicating spatial scalability means information identifying dependency on NAL unit. In describing the configuration information, FIG. 3 is referred to. For instance, the dependency may vary in accordance with spatial resolution. In FIG. 3, layers in Spa_Layer0 and Spa_Layer1 can have the same resolution. Layers in Spa_Layer0 can include pictures obtained by performing downsampling on layers in Spa_Layer1. In particular, for example, assuming that information identifying dependency on NAL unit is represented as dependency_id, layers in Spa_Layer0 may have the relation of dependency_id=0. And, layers in Spa_Layer1 may have the relation of dependency_id=1. The dependency identification information can be defined in various ways. Thus, NAL units having the same value as the information identifying the dependency can be represented as dependency representation.

Meanwhile, a single layer can be defined in accordance with the information identifying the dependency and the quality identification information. In this case, NAL units having the same values as the information identifying the dependency and the quality identification information can be represented as layer representation.

Identification information indicating temporal scalability means information identifying a temporal level for NAL unit. The temporal level can be described in a hierarchical B picture structure. For instance, a layer (B1, Q1) and a layer (B3, Q3) in Spa_Layer0 can have an identical temporal level Tem_Layer0. If a layer (B5, Q5) refers to a layer (B1, Q1) and a layer (B3, Q3), the layer (B5, Q5) can have a temporal level Tem_Layer1 higher than a temporal level Tem_Layer0 of the layer (B1, Q1) and the layer (B3, Q3). Likewise, if a layer (B7, Q7) refers to a layer (B1, Q1) and a layer (B5, Q5), the layer (B7, Q7) can have a temporal level Tem_Layer2 higher than a temporal level Tem_Layer1 of the layer (B5, Q5). All the NAL units within a single access unit can have an identical temporal level value. In case of an IDR access unit, the temporal level value may become 0.

Flag information indicating whether a reference base picture is used as a reference picture indicates whether reference base pictures are used as reference pictures in an inter-layer prediction process or decoded pictures are used as reference pictures in the inter-layer prediction process. The flag information can have the same value for NAL units in a same layer, i.e., for NAL units having the same information identifying dependency.

Priority identification information means information identifying a priority of NAL unit. It is possible to provide inter-layer extensibility or inter-picture extensibility using the priority identification information. For instance, it is possible to provide a user with sequences at various temporal and spatial levels using the priority identification information. So, the user is able to view a sequence in specific time and space or a sequence in accordance with a different restriction condition only. The priority information can be configured in various ways in accordance with its reference condition. The priority information can be randomly configured without being based on a special reference. And, the priority information can be determined by a decoder.

And, configuration information in an extension area of NAL unit header can include flag information indicating whether a current access unit is an IDR access unit.

Various information for inter-layer prediction can be included in a slice layer. For instance, information {circle around (5)} indicating a handling of a slice boundary in an upsampling process, information {circle around (6)} associated with an operation of a deblocking filter, information {circle around (7)} related to a phase shift of a chroma signal, offset information {circle around (8)} indicating a position difference between layers, and information {circle around (9)} indicating a presence or non-presence of an execution of adaptive prediction, and the like can be included. The above information can be obtained from a slice header.

As examples of the information {circle around (6)} associated with the operation of the deblocking filter, there may be information (disable_deblocking_filter_idc) indicating an operational method of the deblocking filter, offset information (inter_layer_slice_alpha_c0_offset_div2, inter_layer_slice_beta_offset_div2) necessary for a deblocking filtering execution, and the like.

As examples of the information {circle around (7)} on the phase shift of the chroma signal, there may be informations (scaled_ref_layer_left_offset, scaled_ref_layer_top_offset, scaled_ref_layer right_offset, scaled_ref_layer bottom_offset) on horizontal and vertical phase shifts of a chroma component of a picture used for inter-layer prediction.

As examples of the offset information {circle around (7)} indicating the position difference between layers, there may be offset informations (scaled_ref_layer_left_offset, scaled_ref_layer_top_offset, scaled_ref_layer_right_offset, scaled_ref_layer_bottom_offset) indicating top, bottom, left and right position differences between an upsampled picture used for inter-layer prediction and a current picture.

As an example of the information {circle around (8)} indicating the handling of a macroblock located on slice boundary in the base layer upsampling process, there may be information (constrained_intra_resampling_flag) indicating whether a current macroblock can not be predicted by using corresponding intra-coded block in the first layer in case that a corresponding intra-coded block in the first layer exists over at least two slices in the second layer.

And, the information {circle around (9)} indicating a presence or non-presence of the execution of the adaptive prediction is capable of indicating a presence or non-presence of prediction associated information within a slice header and a macroblock layer. In accordance with the information indicating the presence or non-presence of the execution of the adaptive prediction, it is able to decide what kind of an adaptive prediction method will be used. This will be explained in detail with reference to FIG. 11 later.

FIG. 4 is a diagram for a cropping relation between a sampled base layer and an enhanced layer.

In scalable video coding, it is possible to check whether a current block of an enhanced layer can use inter-layer prediction. For instance, it is possible to check whether an area corresponding to all pixels within a current block exists in a base layer. As a result of the checking process, if the current block of the enhanced layer is not used for inter-layer prediction, it is unnecessary to transport coding information used for inter-layer prediction. Hence, it is able to raise a coding efficiency.

Thus, it is able to define a function capable of checking whether a current block of an enhanced layer can use inter-layer prediction. For instance, a function ‘in_crop_window( )’ can be defined as a function for checking whether an area corresponding to all pixels within a current block exists in a base layer. Assuming that a macroblock index in a horizontal direction on an enhance layer is set to ‘mbIdxX’ and a macroblock index in a vertical direction is set to ‘mbIdxY’, if the following conditions are met, the function in_crop_windowo can return a value ‘TRUE (or ‘1’)’

mbIdxX≧(ScaledBaseLeftOfffset+15)/16

mbIdxX≦(ScaledBaseLeftOffset+ScaledBaseWidth−1)−16

mbIdxY≧(ScaledBaseTopOffset+15)/16

mbIdxY≦(ScaledBaseTopOffset+ScaledBaseHeight−1)/16

The ‘mbIdxX’ can be derived using a macroblock address and the number of macroblocks in the horizontal direction. The ‘mbIdxY’ can be derived by a method differing according to whether application of macroblock adaptive frame-field is applied or not. For instance, if the macroblock adaptive frame-field is applied, it can be derived by considering a macroblock pair. In considering the macroblock pair, it is assumed that an index of a top macroblock is set to ‘mbIdxY0’ and that an index of a bottom macroblock is set to ‘mbIdxyY1’. The ‘mbIdxY0’ can be derived from offset information indicating a top position difference between an upsampled picture used for inter-layer prediction and a current picture and macroblock number information in a horizontal direction. In this case, a value of the horizontal macroblock number information may differ in accordance with whether a current picture is a frame picture or a field picture. The ‘mbIdxY1’ can be derived from offset information indicating a top position difference between an upsampled picture used for inter-layer prediction and a current picture and macroblock number information in a vertical direction. Meanwhile, if the macroblock adaptive frame-field is not applied, the ‘mbIdxY0’ and the ‘mbIdxY1’ can be set to the same value.

The ‘ScaledBaseLeftOffset’ indicates offset information indicating a left position difference between an upsampled picture used for inter-layer prediction and a current picture. The ‘ScaledBaseTopOffset’ indicates offset information indicating a top position difference between an upsampled picture used for inter-layer prediction and a current picture. The ‘ScaledBaseWidth’ indicates a horizontal width of an upsampled picture. And, the ‘ScaledBaseHeight’ indicates a vertical height of an upsampled picture.

If any one of the above conditions is not satisfied, the function in_crop_window( ) can return a value of ‘FALSE (or ‘0’)’.

In case that a pixel corresponding to at least one pixel within a current block (CurrMbAddr) is not in an upsampled base layer, i.e., in case that the function in_crop_window(CurrMbAddr) returns the value of ‘FALSE’, information associated with inter-layer prediction is not used for the current block and this information may not be transported. Hence, according to the embodiment of the present invention, if it is identified that the corresponding base layer area does not exist via the in_crop_window(CurrMbAddr), it is able to omit the transport of the information associated with the inter-layer prediction for the current block.

According to one embodiment of the present invention, a case of performing coding by using the function in_crop_window( ) is explained as follows.

First of all, in case that it is identified that an area corresponding to a current block exists in a base layer via ‘in_crop window(CurrMbAddr)’, the enhanced layer encoding unit 106 performs inter-layer prediction using texture and/or motion information of the base layer. In this case, the motion information can include reference index information, motion vector information, partition information, etc.

In case that texture and/or motion information of the current block is set to the texture and/or motion information of the corresponding block or in case that texture and/or motion information of the current block is derived from the texture and/or motion information of the corresponding block, the enhanced layer encoding unit 106 adds instruction information instructing the intact or derived information to a data stream of an enhanced layer, and then informs the decoder 110 of the addition. But, in case that it is identified that an area corresponding to a current block does not exist in a base layer via ‘in_crop_window(CurrMbAddr)’, the enhanced layer encoding unit 106 is able to generate an enhanced layer without performing inter-layer prediction. Meanwhile, if the decoder 110 confirms that an area corresponding to a current block does not exist in a base layer via ‘in_crop_window(CurrMbAddr)’, the decoder 110 decides that the instruction information has not been transmitted.

FIG. 5 and FIG. 6 are diagrams for syntaxes relevant to macroblock and sub-macroblock predictions through inter-layer prediction according to one embodiment of the present invention, respectively.

In case of performing inter-layer prediction, information associated with inter-layer prediction in slice data of a current NAL is transported to a decoder. For instance, in case of motion vector prediction of a current block of an enhanced layer, a flag (motion_prediction_flag_lx) indicating whether to use a motion vector of a base layer can be obtained from a macroblock layer. According to an embodiment of the present invention, the decoder is able to know whether the information associated with inter-layer prediction is transported by an encoder in a manner of checking ‘in_crop_window(CurrMbAddr)’ [510, 610]. For instance, if an area corresponding to a current block does not exist in a base layer in accordance with the ‘in_crop_window(CurrMbAddr)’, the flag ‘motion_prediction_flag_(—)10/11’ may riot be transported on a bit stream [520/530, 620/630].

And, a flag ‘adaptive motion_prediction flag’ indicating whether information associated with motion vector prediction is present within a macroblock layer can be obtained from slice data of a current NAL. According to an embodiment of the present invention, information associated with inter-layer prediction may not be transported by the encoder in a manner of checking both of the ‘adaptive motion_prediction_flag’ and the ‘in_crop_window(CurrMbAddr)’ [510]. For instance, if an area corresponding to a current block does not exist in a base layer in accordance with the ‘in_crop_window(CurrMbAddr)’ or if information associated with motion vector prediction does not exist within a macroblock in accordance with the ‘adaptive_motion_prediction_flag’, the flag ‘motion_prediction_flag_(—)10/11’ may not be transported [520/530, 620/630]. The above-described technical idea is identically applicable to sub-macroblock prediction shown in FIG. 6.

Thus, only if both of the two kinds of conditions are satisfied after identification of the two kinds of informations, the information associated with inter-layer prediction is transported. Hence, a coding efficiency can be raised.

FIG. 7 is a diagram of a syntax relevant to residual prediction through inter-layer prediction according to one embodiment of the present invention.

In case of performing inter-layer prediction, information associated with inter-layer prediction in slice data of a current NAL is transported to a decoder. For instance, in case of predicting a residual signal of a current block, a flag ‘residual_prediction_flag’ indicating whether to use a residual signal of a base layer can be obtained from a macroblock layer [740]. In this case, the base layer can be known using layer representation information. According to an embodiment of the present invention, information associated with inter-layer prediction may not be transported by an encoder in a manner of confirming the ‘in_crop_window(CurrMbAddr)’.

For instance, the ‘residual_prediction_flag’ can be obtained in accordance with information ‘adaptive residual_prediction_flag’ indicating a presence of information associated with prediction of a residual signal within a macroblock and information of a slice type of current block [710]. The ‘residual_prediction_flag’ also can be obtained according to ‘base_mode_flag’. The ‘base_mode_flag’ indicates that whether a type (mb_type) of a current macroblock is derived from a corresponding area of a base layer [720]. The ‘residual_prediction_flag’ also can be obtained according to a type of the current macroblock and the function in_crop_window(CurrMbAddr). For example, The ‘residual_prediction_flag’ can be obtained when a type of macroblock and sub-macroblock is not intra mode [MbPartPredType(mb_type, 0) !=Intra_(—)16×16(8×8 and 4×4)] and the value of in_crop_window(CurrMbAddr) is ‘true’, which means that an area corresponding to a current macroblock exists in a base layer [730]. If the type of the current macroblock is not the intra mode or the area corresponding to a current macroblock do not exist in the base layer [in_crop_window(CurrMbAddr)=0], the residual prediction is not performed. And, the encoder 102 generates an enhanced layer while the ‘residual_prediction_flag’ is not included.

If the ‘residual_prediction flag’ is set to ‘1’, a residual signal of a current block is predicted from a residual signal of the base layer. If the ‘residual_prediction_flag’ is set to ‘0’, a residual signal is encoded without a inter-layer prediction. If the “residual_prediction_flag” does not exist in macroblock layer, it can be derived as follows. For instance, only if the following conditions are entirely satisfied, the ‘residual_prediction flag’ can be derived into a preset value (default_residual_prediction_flag). First of all, ‘base_mode_flag’ should be set to ‘1’ or a type of a current macroblock should not be an intra mode. Secondly, ‘in_crop_window(CurrMbAddr)’ should be set to ‘1’. Thirdly, a flag ‘no_inter_layer_pred_flag’ indicating whether inter-layer prediction is used should be set to ‘0’. Fourthly, a slice type should not be an EI slice. Otherwise, it can be derived into ‘0’.

When an area corresponding to a current sequence block does not exist in a base layer via ‘in_crop_window(CurrMbAddr)’, the enhanced layer decoding unit 116 decides that motion prediction flag (motion_prediction_flag) information does not exist in a macroblock or a sub-macroblock and reconstructs a video signal using a data bit stream of an enhanced layer only without inter-layer prediction. If a syntax element for the residual prediction is not included in a data bit stream of an enhanced layer, the enhanced layer decoding unit 116 is able to derive a residual prediction flag ‘residual_prediction_flag’. In doing so, it is able to consider whether an area corresponding to a current block exists in a base layer via ‘in_crop_window(CurrMbAddr)’. If the ‘in_crop_window(CurrMbAddr)’ is set to ‘0’, the enhanced layer decoding unit 116 can confirm that the area corresponding to the current sequence block does not exist in the base layer. In this case, the ‘residual_prediction_flag’ is derived into ‘0’ and then is able to reconstruct a video signal using data of an enhanced layer only without residual prediction using a residual signal of the base layer.

FIG. 8 is a diagram of a syntax structure to perform deblocking filtering in accordance with a presence or non-presence of inter-layer prediction execution according to an embodiment of the present invention.

First of all, according to an embodiment of the present invention, an encoder may not transfer information associated with inter-layer prediction by checking configuration information of the scalable-video-coded bit stream. The configuration information of the scalable-video-coded bit stream can be obtained from an extension area of NAL header. For instance, information associated with an operation of a deblocking filter can be obtained in accordance with information (no_inter_layer_pred_flag) indicating whether inter-layer prediction is used and quality identification information (quality_id) (810). As examples of the information associated with the operation of the deblocking filter, there may exist information (disable_deblocking_filter_idc) indicating an operational method of the deblocking filter, offset information (slice_alpha_c0_offset_div2, slice_beta_offset_div2) required for deblocking filtering, and the like.

First of all, it is able to obtain the information indicating the operational method of the deblocking filter based on information for controlling characteristics of the deblocking filter. In this case, as mentioned in the description of FIG. 2, the information for controlling characteristics of the deblocking filter can be obtained from the extension area of the sequence parameter set. For instance, as the information for controlling characteristics of the deblocking filter, there may exist flag information (inter_layer_deblocking_filter_cont_rol_present_flag) indicating whether there exists the information for controlling characteristics of the deblocking filter for inter-layer prediction (820). Hence, the information indicating the operational method of the deblocking filter is able to be obtained in accordance with the flag information (830).

In particular, if disable_deblocking_filter_idc=0, filtering can be carried out on all block edges of luminance and chrominance signals of a current picture. If disable_deblocking_filter_idc=1, filtering may not be carried out on all block edges of a current picture. disable_deblocking_filter_idc=2, filtering can be carried out on all block edges except block edges having slice boundary overlapped. If disable_deblocking_filter_idc=3, filtering is carried out on a block edge having a slice boundary not overlapped and then filtering is carried out on block edges having a slice boundary overlapped. If disable_deblocking_filter_idc=4, filtering is carried out on a block edge of a luminance signal only but may not be carried out on a block edge of a chrominance signal. If disable_deblocking_filter_idc=5, filtering is carried out on all block edges of luminance signal except block edges having a slice boundary overlapped and may not be carried out on a block edge of a chrominance signal. If disable_deblocking_filter_idc=6, filtering is not carried out on a block edge of a chrominance signal but may be carried out on a block edge of a luminance signal only. After filtering has been carried out on a block edge of a luminance signal having a slice boundary not overlapped, filtering can be carried out on block edges of a luminance signal having a slice boundary overlapped.

Based on the information indicating the operational method of the deblocking filter, it is able to obtain offset information required for deblocking filtering. For instance, if disable_deblocking_filter_idc=1, deblocking filtering is not carried out on all block edges. So, it is able to obtain the offset information required for the deblocking filtering only if a value of ‘disable_deblocking_filter_idc’ is not set to 1 (840). For instance, ‘inter_layer_slice_alpha_c0_offset_div2’ and ‘inter_layer_slice_beta_offset_div2’ may mean offset information used in accessing a deblocking filter table within macroblock in inter-layer prediction (850). Hence, it is able to perform deblocking filtering using the obtained offset information.

FIG. 9 is a diagram of a syntax structure to obtain offset information indicating a position difference between an up-sampled picture and a current picture in accordance with a presence or non-presence of inter-layer prediction execution according to an embodiment of the present invention.

First of all, according to an embodiment of the present invention, an encoder may not transfer information associated with inter-layer prediction by checking configuration information of the scalable-video-coded bit stream. The configuration information of the scalable-video-coded bit stream can be obtained from an extension area of NAL header. For instance, information related to a parameter for an up-sampling process can be obtained in accordance with information (no_inter_layer_pred_flag) indicating whether inter-layer prediction is used and quality identification information (quality_id) (910). As examples of the information related to the parameter for the up-sampling process, there may exist information on a phase shift of a chrominance signal (930), offset information (940) indicating a position difference between pictures, and the like. And, the informations related to the parameter for the up-sampling process can be obtained from an extension area of a sequence parameter set and a slice header.

As examples of the information (930) on the phase shift of the chrominance signal, there may exist information (ref_layer_chroma_phase_x_plus1) on a horizontal phase shift of a chrominance component of a picture used for inter-layer prediction, information (ref_layer_chroma_phase_y_plus1) on a vertical phase change thereof. As examples of the offset information (940) indicating the position difference between the pictures, there may exist offset informations (scaled_ref_layer_left_offset, scaled_ref_layer_top_offset, scaled_ref_layer_right_offset, scaled_ref_layer_bottom_offset) indicating left, top, right and bottom position differences between an up-sampled picture used for inter-layer prediction and a current picture.

The informations related to the parameter for the up-sampling process can be obtained based on information (extended_spatial_scalability) indicating a position of the informations related to the parameter for the up-sampling process. For instance, if the extended_spatial_scalability is set to 0, it may mean that the informations related to the parameter for the up-sampling process exist in neither a sequence parameter set nor a slice header. If the extended_spatial_scalability is set to 1, it may mean that the informations related to the parameter for the up-sampling process exist not in a slice header but in a sequence parameter set. If the extended_spatial scalability is set to 2, it may mean that the informations related to the parameter for the up-sampling process exist not in a sequence parameter set but in a slice header. Hence, if the extended_spatial_scalability is set to 2, it is able to control the informations related to the parameter for the up-sampling process within the slice header (920). Moreover, if the extended_spatial_scalability is set to 1, it is able to control the informations related to the parameter for the up-sampling process within the sequence parameter set.

The information (930) on the phase shift of the chrominance signal and the offset information (940) indicating the position difference between the pictures are usable for the up-sampling process as well.

FIG. 10 is a diagram of a syntax structure to obtain flag information indicating whether to restrict a use of intra-block in a reference layer in accordance with a presence or non-presence of inter-layer prediction execution according to an embodiment of the present invention.

First of all, according to an embodiment of the present invention, an encoder may not transfer information associated with inter-layer prediction by checking configuration information of the scalable-video-coded bit stream. The configuration information of the scalable-video-coded bit stream can be obtained from an extension area of NAL header. For instance, information indicating a handling of a slice boundary in an up-sampling process can be obtained in accordance with information (no_inter_layer_pred_flag) indicating whether inter-layer prediction is used and quality identification information (quality_id) (1010). As an example of the information indicating the handling of the slice boundary, there may exist information (constrained_intra_resampling_flag) indicating whether to restrict a use of intra-block in a first layer for a current block in a second layer (1020). By defining the information indicating whether to restrict a use of intra-block, it is able to improve a decoding speed in executing parallel processing. The information indicating whether to restrict a use of intra-block can be obtained from a slice header.

Since the information indicating whether to restrict a use of intra_block can be obtained from the slice header, even if its value is set to L, it is necessary to check whether a reference block of the first layer corresponding to a current block is included in a specific slice of the first layer. So, it is able to confirm whether the reference block of the first layer corresponding to a current block is included in the specific slice of the first layer when the constrained_intra_resampling_flag is set to 1. For instance, in case that a reference block in a first layer overlaps at least two slices in the first layer, a current block is marked as a non-use of an intra-block in the first layer. In particular, it is unable to code the current block using an intra-base prediction mode. The intra-base prediction mode may mean a mode for predicting a current block of an enhanced layer based on a correspondent area of a base layer. In this case, the correspondent area of the base layer may mean a block coded in an intra-mode. In case that the correspondent area of the first layer is included in a specific slice of the first layer, it is able to decode the current block using an intra-block in the first layer. In this case, the current block can be marked as a use of an intra-base prediction mode.

If the constrained_intra_resampling_flag is set to 1, information (disable_deblocking_filter_idc) indicating the operational method of the deblocking filter described with reference to FIG. 8 may be restricted. For instance, the disable_deblocking_filter_idc can be set to 1, 2, or 4 only.

If the constrained_intra resampling_flag is set to 0, even if a corresponding block in a first layer overlaps at least two slices in the first layer, it is able to decode a current block in a second layer using an intra-block in the first layer.

The above-described embodiments are applicable to a chrominance signal as well as a Luminance signal in the same manner.

FIG. 11 is a diagram of a syntax for obtaining adaptive prediction information in accordance with a presence or non-presence of inter-layer prediction execution according to one embodiment of the present invention.

According to an embodiment of the present invention, in a manner of confirming configuration information of the scalable-video-Coded bit stream, information associated with inter-layer prediction may not be transported by an encoder. The configuration information of the scalable-video-coded bit stream can be obtained from an extension area of a NAL header. For instance, adaptive prediction information can be obtained based on information ‘no_inter_layer_pred_flag’ indicating whether inter-layer prediction is used [1110]. The adaptive prediction information can indicate whether a syntax associated with prediction exists in a corresponding position. For instance, there may exist information ‘adaptive_prediction_flag’ indicating whether a syntax associated with prediction exists in a slice header and a macroblock layer, information ‘adaptive_motion_prediction_flag’ indicating whether a syntax associated with motion prediction exists in a macroblock layer, information ‘adaptive residual_prediction_flag’ indicating whether a syntax associated with residual prediction exists in a macroblock layer, and the like.

In case that inter-layer prediction is carried out in accordance with the information indicating whether the inter-layer prediction is used, a flag information ‘slice_skip_flag’ indicating a presence or non-presence of slice data can be firstly obtained [1120]. By confirming the information indicating the presence of the slice data, it is able to decide whether to derive informations within a macroblock to perform inter-layer prediction. In accordance with the information indicating the presence of the slice data, if the slice data exists within the slice [1130], it is able to obtain an adaptive prediction flag ‘adaptive_prediction_flag’ [1140]. And, it is also able to obtain information ‘adaptive_residual_prediction_flag’ indicating whether a syntax associated with residual prediction exists in a macroblock layer [1180]. In accordance with the adaptive prediction flag, it is able to obtain information ‘default_base_mode_flag’ indicating how to derive information that indicates whether to predict motion information and the like from a correspondent block of the base layer [1150]. In case that the motion information and the like are not predicted from a correspondent block of the base layer [1155], it is able to obtain information ‘adaptive motion_prediction flag’ indicating whether a syntax associated with motion prediction exists in the macroblock layer [1160]. If the syntax associated with motion prediction does not exist in the macroblock layer [1165], it is able to obtain information ‘default_motion_prediction_flag’ indicating how to infer motion prediction flag information [1170].

The information ‘adaptive motion_prediction_flag’ indicating whether the syntax associated with motion prediction exists in the macroblock layer and the information ‘adaptive_residual_prediction_flag’ indicating whether the syntax associated with residual prediction exists in the macroblock layer are usable within the macroblock layer. For instance, it is able to obtain a flag ‘motion_prediction_flag_lx’ indicating whether to use a motion vector of the base layer based on the ‘adaptive motion_prediction_flag’. And, it is able to obtain a flag ‘residual_prediction flag’ indicating whether to use a residual signal of the base layer based on the ‘adaptive_residual_prediction_flag’.

As mentioned in the foregoing description, the decoder/encoder, to which the present invention is applicable, is provided to a broadcast transmitter/receiver for multimedia broadcasting such as DMB (digital multimedia broadcasting) to be used in decoding video signal, data signals, etc. And, the multimedia broadcast transmitter/receiver can include a mobile communication terminal.

A decoding/encoding method, to which the present invention is applied, is configured with a program for computer execution and then stored in a computer-readable recording medium. And, multimedia data having a data structure of the present invention can be stored in computer-readable recording medium. The computer-readable recording media include all kinds of storage devices for storing data that can be read by a computer system. The computer-readable recording media include ROM, RAM, CD-ROM, magnetic tapes, floppy discs, optical data storage devices, etc. and also includes a device implemented with carrier waves (e.g., transmission via internet). And, a bit stream generated by the encoding method is stored in a computer-readable recording medium or transmitted via wire/wireless communication network.

INDUSTRIAL APPLICABILITY

Accordingly, while the present invention has been described and illustrated herein with reference to the preferred embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made therein without departing from the spirit and scope of the invention. Thus, it is intended that the present invention covers the modifications and variations of this invention that come within the scope of the appended claims and their equivalents. 

1. A method of decoding a video signal, comprising: decoding a bit stream of a base layer; obtaining flag information indicating whether an inter-layer prediction is carried out on a current block of an enhanced layer; obtaining information indicating an obtaining position of parameters, the parameters including at least one of information on a phase shift of a chrominance signal and offset information; obtaining the information on the phase shift of the chrominance signal based on the flag information and the information indicating the obtaining position of the parameters; obtaining the offset information based on the flag information and the information indicating the obtaining position of the parameters, the offset information indicating a position difference between a reference picture up-sampled from a picture of the base layer and a current picture including the current block; up-sampling the picture of the base layer; and decoding a bit stream of the enhanced layer based on the reference picture up-sampled from the picture of the base layer, the information on the phase shift of the chrominance signal and the offset information.
 2. The method of claim 1, wherein the information indicating the obtaining position of the parameters indicates that the parameters exist in a sequence parameter set, a slice header, or neither the sequence parameter set nor the slice header.
 3. The method of claim 1, wherein the information on the phase shift of the chrominance signal is obtained based on information indicating a chroma format.
 4. The method of claim 1, wherein the information on the phase shift of the chrominance signal includes horizontal phase shift information and vertical phase shift information.
 5. The method of claim 1, further comprising obtaining quality identification information identifying an image quality of the picture including the current block, wherein the offset information is obtained based on the quality identification information.
 6. The method of claim 1, wherein the enhanced layer differs from the base layer in an image quality or a spatial resolution.
 7. The method of claim 1, wherein the video signal is received as a broadcast signal.
 8. The method of claim 1, wherein the video signal is received via a digital medium.
 9. An apparatus for decoding a video signal comprising: a base layer decoding unit decoding a bit stream of a base layer; a first header information obtaining unit obtaining flag information indicating whether an inter-layer prediction is carried out on an enhanced layer; a second header information obtaining unit obtaining information indicating an obtaining position of parameters, the parameters including at least one of information on a phase shift of a chrominance signal and offset information; the second header information obtaining unit obtaining the information on the phase shift of the chrominance signal based on the flag information and the information indicating the obtaining position of the parameters; the second header information obtaining unit obtaining the offset information based on the flag information and the information indicating the obtaining position of the parameters, the offset information indicating a position difference between a reference picture up-sampled from a picture of the base layer and a current picture including the current block; an up-sampling unit up-sampling the picture of the base layer; and an enhanced layer decoding unit decoding a bit stream of the enhanced layer based on the reference picture up-sampled from the picture of the base layer, the information on the phase shift of the chrominance signal and the offset information. 